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DNA and RNA editing without sequence limitation using the flap endonuclease 1 guided by hairpin DNA probes.

ABSTRACT: Here, we characterized a flap endonuclease 1 (FEN1) plus hairpin DNA probe (hpDNA) system, designated the HpSGN system, for both DNA and RNA editing without sequence limitation. The compact size of the HpSGN system make it an ideal candidate for in vivo delivery applications. In vitro biochemical studies showed that the HpSGN system required less nuclease to cleave ssDNA substrates than the SGN system we reported previously by a factor of ?40. Also, we proved that the HpSGN system can efficiently cleave different RNA targets in vitro. The HpSGN system cleaved genomic DNA at an efficiency of ?40% and ?20% in bacterial and human cells, respectively, and knocked down specific mRNAs in human cells at a level of ?25%. Furthermore, the HpSGN system was sensitive to the single base mismatch at the position next to the hairpin both in vitro and in vivo. Collectively, this study demonstrated the potential of developing the HpSGN system as a small, effective, and specific editing tool for manipulating both DNA and RNA without sequence limitation.

SUBMITTER: Tian K 

PROVIDER: S-EPMC7672438 | biostudies-literature | 2020 Nov

REPOSITORIES: biostudies-literature

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DNA and RNA editing without sequence limitation using the flap endonuclease 1 guided by hairpin DNA probes.

Tian Kun K   Guo Yongjian Y   Zou Bingjie B   Wang Liang L   Zhang Yun Y   Qi Zhen Z   Zhou Jieying J   Wang Xiaotang X   Zhou Guohua G   Wei Libin L   Xu Shu S  

Nucleic acids research 20201101 20

Here, we characterized a flap endonuclease 1 (FEN1) plus hairpin DNA probe (hpDNA) system, designated the HpSGN system, for both DNA and RNA editing without sequence limitation. The compact size of the HpSGN system make it an ideal candidate for in vivo delivery applications. In vitro biochemical studies showed that the HpSGN system required less nuclease to cleave ssDNA substrates than the SGN system we reported previously by a factor of ∼40. Also, we proved that the HpSGN system can efficientl  ...[more]

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